JPH1155152A - Transmitter/receiver for base station - Google Patents

Abstract

(57) [Problem] To establish synchronization of transmission / reception timing between base stations using an air synchronization method. SOLUTION: When the transmission / reception timing cannot be synchronized with the same place or another nearby station, or when it is necessary to synchronize, a synchronization control unit SYCC outputs a reception mode switching signal V _CONT to synchronize. Set to the control reception mode. As a result, the attenuating means ATT attenuates a strong input signal from another station, inputs the signal to the demodulation unit DM via the front end FE, and the demodulation unit demodulates the received data. Synchronization control unit S
The YCC detects synchronization information (synchronization word UW) from the received data, synchronizes, and returns the reception mode to the normal reception mode.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission / reception apparatus of a base station which repeats a transmission mode and a reception mode, transmits a signal in the transmission mode, and receives a signal in the reception mode, and in particular, a PHS (Personal Handyphone system).
The present invention relates to a transmission / reception apparatus of a mobile communication base station using TDD (Time Divisional Duplex).

[0002]

2. Description of the Related Art In order to reduce the load on the hardware on the terminal side and realize a small size, light weight, and a long standby time, a PH is used.
S realizes bidirectional information transmission by TDD.
TDD performs transmission and reception alternately in a time-division manner.
For example, in the case of PHS, 4-channel multiplex TDMA-TD
The transmission / reception timing of the D system is as shown in FIG.
625 μs slots for transmission 4 (CH1 TX to CH4 TX) and reception 4 (CH1 RX to CH4RX) are exchanged during one frame of 5 ms. In FIG. 23, CS (Cell Station) is a base station,
PS1 to PS4 (PS: Personal Station) are slave stations which are mobile stations, TS is a transmission mode period of the base station, and RS is a reception mode period of the base station. Four slave stations PS from base station CS
Information is transmitted to 1 to PS4 as a burst signal of 625 μs in 5 ms at the timing shown in FIG.
Further, each of the slave stations PS1 to PS4 transmits the transmission information of the own station for 625 μs 2.5 ms after receiving the signal from the base station CS.
, Transmit in bursts.

[0003] Recently, when a plurality of PHS carriers have densely arranged base stations in the same area, transmission / reception interference becomes a problem. This is because frames are not synchronized between PHS carriers, so if a base station is started up independently,
This is because the transmission slot of the base station of the operator A overlaps the reception slot of the base station of the operator B, which is adjacent to the base station, and interferes with the reception of radio waves from the slave station of the operator B.

In order to solve such a problem, it is easiest to transmit a frame synchronization signal between base stations via a cable, and to switch transmission / reception timing in accordance with the frame synchronization signal received by each station. However, each base station is usually installed independently, and it is not easy and practical to connect base stations with cables even in the building immediately adjacent. Further, if a frame synchronization signal is to be transmitted using a general line, a synchronization network is constructed by itself, which is not economical. As one of means for avoiding the above-mentioned problems caused by cable transmission, a method called air synchronization is used. The air synchronization method is a method in which a base station that enters operation later receives radio waves from a base station that has already started operation and starts up in synchronization with the radio wave.

[0005]

According to the air synchronization method,
In the process of establishing transmission / reception timing synchronization, it is necessary for the base station to perform an unusual operation of receiving a radio wave emitted by another base station. For this reason, excessive input to the receiver of the base station poses a problem. Since the base station has a higher transmission output than the slave station, a radio wave emitted at a short distance becomes an excessive input for the base station receiving the radio wave, and the characteristic of the front-end low-noise amplifier is degraded or, at worst, damaged. Constructing a low-noise amplifier using a device with a large input resistance increases noise characteristics and lowers the receiving sensitivity, and is not an effective solution. When base stations of different PHS operators are installed in a nearby building, or when a plurality of base station devices are installed in one place to increase the number of subscribers for applications such as WLL (Wireless Local Loop), In particular, the above problems are often encountered.

Accordingly, it is an object of the present invention to establish synchronization of transmission / reception timing between base stations by using an air synchronization method, without causing deterioration or breakage of characteristics of a low noise amplifier, and further, receiving sensitivity. It is an object of the present invention to provide a transmission / reception device of a base station which does not reduce the transmission power. Another object of the present invention is to provide a base station transmitting / receiving apparatus which eliminates restrictions on the installation location of a base station, thereby enabling an effective installation of a base station.

[0007]

[Means for Solving the Problems]

(A) First Solution FIG. 1 is a configuration diagram of a base station transmitting / receiving apparatus for explaining a first solution of the present invention. TPA is a transmission power amplifier that is turned on during the transmission mode period TS (see FIG. 23) and is turned off during the reception mode period RS, FE is a front end that performs amplification and frequency conversion of a received signal, and DM is provided behind the front end and receives data. A demodulation unit for demodulating data from a signal, ANT is an antenna, ANT-SW is an antenna switch for appropriately connecting the antenna to the transmission side and reception side, and AT is provided between the front end and the antenna switch to pass / attenuate an input signal. Attenuating means, TRMG is a signal generating unit for generating a transmission / reception identification signal TRS indicating whether the mode is the transmission mode period or the reception mode period, and SYCC is the first and second reception modes (normal reception mode, synchronous control reception mode) _Is a synchronization control unit that generates a signal V _CONT for instructing the switching of. The first reception mode is a normal reception mode, and the second reception mode is a synchronization control reception mode for synchronizing the transmission / reception timing of the own station with the transmission / reception timing of another base station. This is a mode for receiving attenuated signals and synchronizing the own station with other stations using the synchronization information included in the received signal. The attenuating means AT attenuates the input signal during the transmission mode, passes the reception signal in the first reception mode (normal reception mode) during reception, and attenuates the reception signal in the second reception mode (synchronous control reception mode). .

In the case where the transmission and reception timing cannot be synchronized with another station in the same location or in the vicinity, or when it is necessary to synchronize, the synchronization control unit SYCC outputs a reception mode switching signal V _CONT and outputs the second mode. To the reception mode. Thereby, the attenuating means AT attenuates a strong input signal from another station and inputs the signal to the demodulation unit DM via the front end FE.
The demodulation unit demodulates the received data. The synchronization control unit SYCC detects synchronization information from the received data to establish synchronization, and returns the reception mode to the first reception mode. The attenuation means can be constituted by an attenuator or a switch. In this way, the transmission / reception timing synchronization between the base stations can be established using the air synchronization method, and the strong input signal from the other station is attenuated and received. Does not occur, and the receiving sensitivity is not reduced. Further, since the transmission / reception timing of the own station can be synchronized with the transmission / reception timing of another station, there is no restriction on the installation location of the base station, thereby enabling the effective installation of the base station.

(B) Second Solution FIG. 2 is a block diagram of a base station transmitting / receiving apparatus for explaining a second solution of the present invention. The same parts as those in FIG. 1 are denoted by the same reference numerals. The difference from FIG. 1 is the method of attenuating the received signal in the second reception mode (synchronous control reception mode). In FIG. 1, the reception signal is attenuated by the attenuating means (attenuator or switch) AT in the second reception mode, but in FIG. 2, in the second reception mode, the antenna ANT is not connected to the reception side, but is connected to the transmission side. This attenuates the received signal. That is, the received signal is attenuated by inputting the leakage signal in the switch to the front end. The attenuating means AT passes the input signal without performing the attenuating operation in the first and second receiving modes, and performs the attenuating operation only at the time of transmission.

When the transmission / reception timing cannot be synchronized with the same place or another nearby station, or when it is necessary to synchronize, the synchronization control unit SYCC outputs the reception mode switching signal V _CONT and outputs the second reception mode switching signal V _CONT . To the reception mode. As a result, the antenna switch ANT-SW is connected to the antenna A
NT is connected to the transmitting circuit side and not connected to the receiving side. Therefore, a strong input signal from another station is attenuated as a leak in the switch, and is input to the demodulation unit DM via the front end FE, and the demodulation unit demodulates the received data. Synchronization control unit S
The YCC detects the synchronization information from the received data, synchronizes, and returns the reception mode to the first reception mode. In this way, synchronization of transmission and reception timing between base stations can be established using the air synchronization method, and strong input signals from other stations are attenuated in the switch. Does not occur, and the receiving sensitivity is not reduced. Also, since the transmission / reception timing of the own station can be synchronized with the transmission / reception timing of another station,
Eliminates restrictions on where to install base stations,
Effective installation of base stations becomes possible.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION

(A) First Embodiment (a) Overall Configuration FIG. 3 is a configuration diagram of a base station transmitting / receiving apparatus according to a first embodiment of the present invention, and shows an example in which a receiving system has two branches. In the figure,
Reference numerals 1 and 2 denote both transmitting and receiving antennas, two of which are provided for diversity reception. Reference numeral 3 denotes an antenna switch for switching the antennas 1 and 2 which are shared for transmission and reception to the transmission system and the reception system in a time-division manner, and connects the antenna 1 or the antenna 2 to the transmission system during the transmission mode period. The antennas 1 and 2 are connected to the first and second receiving systems, respectively. Reference numeral 4 denotes a transmission / reception control unit which receives a timing signal and outputs a transmission / reception identification signal TRS which is at a low level during the transmission mode period TS (see FIG. 23) and at a high level during the reception mode period RS. 5 is QPS
A demodulation unit that demodulates received data by K demodulation processing, 6 is a first reception system, 7 is a second reception system, 8 is a transmission system, 9 is to synchronize the transmission / reception timing of its own station with the transmission / reception timing of another station and receive A synchronous control circuit 10 that outputs the mode switching signal V _CONT is an attenuator control signal generator that generates an attenuator control signal Vc.

In the first and second receiving systems 6, 7, 11, 11,
Reference numeral 21 denotes an attenuator having a variable attenuation, which attenuates a transmission signal leaked from the antenna switch 3 at the time of transmission and passes a reception signal received by the antennas 1 and 2 at the time of reception. The attenuation of the attenuators 11 and 21 is maximum when the transmission / reception identification signal TRS is low (transmission mode period), and is minimum when the transmission / reception identification signal TRS is high (reception mode period). This prevents the leakage of the transmission wave from the antenna switch 3 during transmission from being excessively input to the front end of the next stage and added thereto, thereby causing deterioration or damage. 1
Reference numerals 2 and 22 denote front ends having a low-noise RF amplifier and a frequency converter, which amplify a 1.9 GHz band received signal and then convert the frequency to a 250 MHz band first intermediate frequency signal.
Reference numerals 13 and 23 denote band-pass filters that pass the first intermediate frequency signal, 14 and 24 denote amplifiers that amplify the first intermediate frequency signal, and 15 and 25 denote the 250 MHz band first intermediate frequency signal.
Frequency converters for down-conversion to a second frequency signal of 10 MHz, 16 and 26 are band-pass filters,
Numerals 7 and 27 amplify the second intermediate frequency signal and output signals RSSI proportional to the received electric field strength of antennas 1 and 2, respectively.
(Received Signal Strength Indicator).

The demodulation unit 5 includes these limiter amplifiers 17, 2
7 is subjected to the maximum ratio combining method (m
aximal-ratio combining) and then Q
The received data is demodulated and output by PSK demodulation. The synchronization control circuit 9 detects the synchronization word UW from the received data output from the demodulation unit 5, and synchronizes the transmission / reception timing of the own station with the transmission / reception timing of another station based on the detection result. In the transmission system, 31 performs QP on a carrier signal by transmission data.
The SK quadrature modulator performs quadrature modulation.
Frequency converter for up-conversion to 9GHz band, 3
Reference numeral 3 denotes a band-pass filter that passes a wireless signal in the 1.9 GHz band. Reference numeral 34 denotes a transmission high-output amplifier (transmission power amplifier) that amplifies the power of the wireless signal and passes through the antenna switch 3 from the antenna 1 or 2 to the air. Radiate.

(B) Attenuator FIG. 4 is a circuit example of the attenuators 11 and 21. As shown in FIG. 5, the attenuation is reduced as the control signal Vc increases. That is, when the control signal Vc is increased, a DC path indicated by a dotted line is formed, and the diode D1 is forward-biased. Therefore, the signal V _IN input to the input terminal is transmitted as V _OUT from the output terminal via the diode D1. On the other hand, when the control signal Vc decreases, a DC path indicated by a dashed line is formed, and the input signal V _IN is output to the output terminal via the capacitor C → the diode D2 → the resistor R → the diode D3 → the capacitor C. Becomes larger. Therefore, the control voltage Vc
Is set to the high level H or the low level L, the attenuation of the attenuator can be controlled to two values.

FIG. 6 is another circuit example of the attenuator.
Switch input signal V_INPassing through / attenuating
You. As shown in FIG. 7, the first control signal
Issue V_{CO NT1}To a high level (= Vcc) and the second control signal
Issue V_CONT2To a low level (= 0). Like this
1, the second control signal V_CONT1, V_CONT2Biasing
A DC path is formed in the direction of the dotted arrow, and the diode D1 is connected.
As a result, the diode D2 becomes non-conductive. Therefore, input
Signal V_INIs V from the output terminal via the diode D1. _OUT
Is sent as On the other hand, the first control
Control signal V_CONT1To the low level (= 0), and the second control signal
Issue V_CONT2To a high level (= Vcc). like this
First and second control signals V_CONT1, V_CONT2Bias
And a DC path is formed in the direction of the dashed line arrow, and the diode
D2 becomes conductive and diode D1 becomes non-conductive. others
Input signal V_INDoes not appear at the output terminal and is attenuated.

(C) Antenna switch FIG. 8 is a diagram showing the configuration of the antenna switch 3. The antenna switch 3 includes three switches 3a to 3c therein, and connects the antenna 1 or the antenna 2 to the transmission system 8 as appropriate. , 2 are connected to the first and second receiving systems 6, 7, respectively. Each of the switches 3a to 3c includes a C terminal to which a signal is input, an A terminal and a B terminal for selectively outputting a signal, and a control terminal for controlling whether the signal is output to either A or B terminal.

FIG. 9 shows an example of a switch circuit. IC1 is a knot gate, and IC2 is an IC circuit. IC circuit IC2
Outputs a low-level signal to terminal a and a high-level signal to terminal b when control signal SWC is at a high level.
When WC is at low level, a high level signal is output to terminal a and a low level signal is output to terminal b. Therefore, the control signal SWC
Is high level, the diode D1 is forward biased,
The diode D2 becomes reverse-biased, and the signal V _IN input from the C terminal is output from the A terminal. Conversely, the control signal S
When WC is at a low level, the diode D1 is reverse biased, the diode D2 is forward biased, and the signal _VIN becomes B
Output from terminal.

(D) Normal Control FIG. 10 is a chart for explaining the operation of the transmission power amplifier 34, the antenna switch 3, and the attenuators 11 and 21 during the normal transmission mode period and the reception mode period. That is, the transmission power amplifier 34 performs an amplification operation during transmission (when the transmission / reception identification signal TRS is low) and stops the amplification operation when receiving (when TRS is high). When transmitting, the antenna switch 3 connects the antenna 1 or the antenna 2 to the transmission system 8.
, And at the time of reception, the antennas 1 and 2 are connected to the first and second receiving systems 6 and 7, respectively. Attenuator 11,
Reference numeral 21 denotes an attenuating operation at the time of transmission, thereby attenuating a transmission signal leaked and inputted to the first and second receiving systems via the antenna switch 3, and a receiving signal received by the antenna 1 and the antenna 2 at the time of reception. Front end 12, without attenuation
Input to 22.

The reason that the attenuators 11 and 21 attenuate at the time of transmission is that the transmission signal amplified by the transmission power amplifier 34 leaks from the antenna switch 3 to the receiving side, and the leakage of the transmission signal causes deterioration of the front ends 12 and 22 and deterioration of the front ends 12 and 22. This is to prevent destruction. For example, the transmission output has an average of about +29 dBm in the burst, and even if it is attenuated by 30 dB due to the isolation of the antenna switch 3, the transmission output is added to the reception system at about 0 dBm. On the other hand, the maximum input level of the front ends 12, 22 is often around -20 dBm. For this reason, the attenuators 11 and 21 are inserted on the input side of the front end to perform an attenuation operation at the time of transmission, thereby attenuating the leakage of the transmission wave and protecting the front end.

When the transmission / reception identification signal TRS goes low at the time of transmission, the transmission power amplifier (PA) 34 performs an amplification operation, and the antenna switch 3 operates the transmission system 8 and the antenna 1.
The attenuators 11 and 21 perform the attenuation operation.
As a result, the radio signal power-amplified by the transmission power amplifier 34 is radiated into the space from the antenna 1, and leakage of the transmission signal is attenuated by the attenuators 11 and 21. When the transmission / reception identification signal TRS goes high during reception, the transmission power amplifier (PA) stops the amplification operation, and the antenna switch 3 connects the antennas 1 and 2 to the first and second reception systems 6 and 7, respectively. , The attenuators 11 and 21 enter the passing state. As a result, the received signals received by the antennas 1 and 2 are amplified and frequency-converted and input to the demodulation unit 5, and the demodulation unit 5 combines the signals input from the first and second reception systems with the maximum ratio combining. After combining by the method, QPSK demodulation is performed to demodulate and output the received data.

(E) Synchronous control A plurality of base stations are placed at one place by WLL (Wireless Local Loop) or the like.
(For example, when installed on both sides of one pillar), the transmission wave of the base station device CS which has been in operation first, the maximum -5dBm
It is calculated that the base station CS reaches the other base station CS in a certain degree, and the base station CS that has started up later in an out-of-synchronization state is exposed to excessive input at the time of reception. The present invention controls the attenuators 11 and 21 when the base station controller CS rises, thereby protecting the front ends 12 and 22 from excessive input until air synchronization is established.

(E-1) Synchronization establishment The transmission slots include a control slot for transmitting broadcast information, general call information, control information necessary for call connection, and a communication slot for transmitting traffic. Base station CS
Transmits control information in a predetermined slot to a slave station in a format shown in FIG. 11A, and transmits control information to a slave station in a predetermined slot (communication slot) in a format shown in FIG. 11B. In the formats of FIGS. 11A and 11B, R is a 4-bit transient response ramp time (burst transient response time) for guaranteeing a rise time, and S
S is a start symbol (fixed to 10) indicating the start of the signal, PR is a clock recovered from the received signal,
Preamble for establishing bit synchronization between slave stations, U
W is a synchronizing word for synchronizing frames.
As shown in FIG. 1C, different patterns are defined for uplink / downlink for control and uplink / downlink for communication. CI is any control channel (broadcast channel,
A channel identifier indicating whether information of a paging channel, an individual cell channel, an information channel, etc.) is being transmitted, I is an information portion of control information and voice data, and CRC is an error check bit.

The synchronization word UW is generated after different times from the heads of the control slot and the communication slot.
Therefore, as shown in FIG. 11A, a window WID having a time width corresponding to UW and CI is set after a time Tw from the detection of the rising edge of the input, and the window WID is set.
If the UW bit pattern of the downlink control channel is detected, it can be determined that the rising time is the beginning of the transmission time slot. In the case of 4-multiplex TDMA-TDD, since the downlink control channel is located in the first slot, the rising time is the rising time of the transmission period of another base station. As described above, if a transmission signal from another base station is received and the rise time of the transmission slot is detected by the above method, the transmission / reception timing of the own station can be synchronized with the transmission / reception timing of the transmission / reception device of the other base station. .

(E-2) Synchronization control of the first embodiment In addition to the normal reception mode, a reception mode (synchronization control reception mode) for synchronizing the transmission / reception timing of the own station with the transmission / reception timing of another station is provided. Then, in the transmission mode / normal reception mode / synchronous control reception mode, the transmission power amplifier 34, the antenna switch 3, and the attenuator 1
1 and 21 are controlled according to the operation explanatory chart shown in FIG. That is, at the time of transmission and normal reception, the transmission power amplifier 34, the antenna switch 3, and the attenuators 11 and 21 are controlled in the same manner as in the operation explanatory diagram of FIG. But,
In the synchronous control reception mode, a strong input signal from another base station is attenuated to control the synchronous control circuit 9 to detect a UW bit pattern. Therefore, in the synchronous control reception mode, the antennas 1 and 2 are connected to the first and second receiving systems 6 and 7, and the attenuators 11 and 21 are attenuated. However, the amplification operation of the transmission power amplifier 34 is stopped.

In the synchronous control reception mode, the attenuator 1
Due to the damping operations of the front ends 12 and 22,
Excessive input to the front end can be attenuated by 20 to 30 dB, and deterioration and breakage of characteristics of the low noise amplifier constituting the front end can be prevented. As described above, after receiving and attenuating a strong signal transmitted from another station, frequency conversion, amplification and input to the demodulation unit 5 are performed, and the demodulation unit demodulates and outputs the received data. The synchronization control circuit 9 detects the synchronization word UW from the received data and synchronizes the transmission / reception timing of the own station with the transmission / reception timing of another station.

(E-3) Attenuator attenuation / pass control FIG. 13 shows an attenuator 1 according to the operation explanatory chart of FIG.
FIG. 3 is a configuration diagram of an attenuator control signal generation unit 10 that passes / attenuates signals 1 and 21. In the figure, reference numeral 4 denotes a transmission / reception control unit for outputting a transmission / reception identification signal TRS which is at a low level during a transmission mode period and at a high level during a reception mode period, and 9 outputs a mode switching signal V _CONT for switching between a normal reception mode and a synchronous control reception mode. A synchronous control circuit 10 generates an attenuator control signal Vc, and an attenuator control signal generator 11 generates an attenuator control signal Vc. Reference numeral 11 denotes an attenuator having the configuration shown in FIG. The attenuator control signal generator 10 has an AND gate 10a that calculates a logical product of the transmission / reception identification signal TRS and the reception mode switching signal V _CONT and outputs an attenuator control signal Vc.

As is clear from FIG. 4, the attenuator 11 passes when the attenuator control signal Vc is at the high level H, and attenuates when the attenuator control signal Vc is at the low level L. Therefore, FIG.
In order to control the attenuator 11 according to the operation explanation chart of (1), (1) Vc = low level L in the transmission mode, (2)
Vc = high level H in the normal reception mode, and (3) Vc = low level L in the synchronous control reception mode. Therefore, the synchronization control circuit 9, as shown in FIG. 14, (1) normal reception mode, mode switching the signal V _CONT to the high level H, the (2) in the synchronous control reception mode, the mode switching signal V _CONT Set to low level L. However, in the transmission mode, the mode switching signal V
_CONT may be either H or L. Thus, the attenuator control signal generator 10 calculates the transmission and reception identification signal TRS and the mode switching signal V _{CO NT} AND, an attenuator control signal Vc generated as shown in FIG. 14 in each mode, the control signal Vc The attenuation / pass control of the attenuators 11, 21 is performed as shown in the operation explanatory diagram of FIG.

(B) Second Embodiment (a) Overall Configuration FIG. 15 is a block diagram of a base station transmitting / receiving apparatus according to a second embodiment of the present invention. The same parts as those in the first embodiment of FIG. Signs are attached. The second embodiment differs from the first embodiment in FIG. 3 in that (1) the attenuator control signal generator 10 is deleted and an antenna switch controller 50 is provided instead, and (2) the operation in FIG. (3) In the synchronous control reception mode, the antenna is not connected to the reception system, but the reception signal is attenuated by connecting the antenna to the transmission system.

(B) Synchronization control In the second embodiment, in the transmission mode / normal reception mode / synchronization control reception mode, the transmission power amplifier 34, the antenna switch 3, and the attenuators 11 and 21 are controlled according to the operation explanatory chart shown in FIG. I do. That is, at the time of transmission and during normal reception, the transmission power amplifier 34, the antenna switch 3, the attenuator 11,
21 is controlled. However, in the synchronous control reception mode, control is performed so that a strong input signal from another base station is attenuated so that the synchronous control circuit 9 can detect a UW bit pattern.
For this reason, in the synchronous control reception mode, the antenna 1,
2 is not connected to the first and second receiving systems 6 and 7, but is connected to the transmitting system 8. In this way, even if a strong input signal is received from another base station, the signal can be prevented from being directly input to the receiving system. That is, a leak signal from the antenna switch 3 becomes an input to the first and second receiving systems 6 and 7, and a strong input signal from another base station is attenuated without being attenuated by the attenuators 11 and 21. By such an attenuating operation, excessive input to the front ends 12 and 22 can be attenuated by 20 to 30 dB, and deterioration and damage of characteristics of the low noise amplifier constituting the front end can be prevented. From the above, the signal transmitted from another station is attenuated by the antenna switch, frequency conversion,
The signal is amplified and input to the demodulation unit 5, which demodulates and outputs the received data. The synchronization control circuit 9 detects the synchronization word UW from the received data and synchronizes the transmission / reception timing of the own station with the transmission / reception timing of another station.

(C) Switching Control of Antenna Switch FIG. 17 shows three switches 3a to 3c constituting the antenna switch 3 (see FIG. 8) according to the operation explanatory chart of FIG.
3 is a table showing signal output terminals and logics (H, L) of control signals. It is necessary to connect the antenna 1 or the antenna 2 to the transmission system 8 at the time of transmission. Therefore, the switches 3a, 3
The signal output terminals of b, 3c are A, A, *. * Means that the output terminal may be either A or B. At the time of normal reception, the antennas 1 and 2 are connected to the first and second reception systems 6 and 7.
Need to be connected to Therefore, the switches 3a, 3b,
The signal output terminal of 3c is set to B, B, *. When receiving the synchronization control, the antennas 1 and 2 must not be connected to the first and second receiving systems 6 and 7. Therefore, the switches 3a, 3b, 3
Set the signal output terminals of c to A, A, *.

As is apparent from FIG. 9, the input signals of the switches 3a to 3c appear at the terminal A when the control signal SWC is at the high level H, and appear at the terminal B when the control signal SWC is at the low level L. Therefore, as shown on the left side of FIG.
1 selects the output terminals A and B, the antenna switch control unit 50 outputs the control signals SWC1 to SWC3 to FIG.
7 must occur at the level shown on the right. During transmission / normal reception / synchronous control reception, the transmission / reception identification signal RTS and the reception mode switching signal V _CONT are as shown in FIG. 18, respectively. Therefore, the antenna switch control unit 50 determines, based on the combination of the logic of the transmission / reception identification signal RTS and the logic of the reception mode switching signal V _CONT ,
Control is performed so as to output the switch control signals SWC1 to SWC3 during transmission / normal reception / synchronous control reception.

That is, when transmitting RTS = L, the antenna switch control unit 50 sets SWC1 and SWC2 to high level and sets SWC3 to arbitrary level. Also, RTS =
During normal reception of H, V _CONT = H, SWC1, SWC2
Is set to a low level, and SWC3 is set to an arbitrary level. Further, in the synchronous control reception mode of V _CONT = L, SWC1
Set SWC2 to a high level (SWC3 is an arbitrary level),
The received signal is attenuated so that it can be input to the first and second receiving systems.

(C) Synchronous Control at Startup of Base Station FIG. 19 is a flowchart of a synchronous control process from the start of the base station to the start of normal operation according to the first or second embodiment. When starting up the base station, a synchronous control reception mode is set (step 101). That is, the mode switching signal V _CONT is set to L by the synchronization control circuit 9. Thereby, the received signal is attenuated by the attenuators 11 and 21 (first embodiment) or attenuated by the antenna switch 3 (second embodiment) regardless of the level of the transmission / reception identification signal TRS. Further, while the mode switching signal V _CONT is at the low level L so that the receiving operation can be performed continuously, the antennas 1 and 2 are connected to the first and second receiving systems (first embodiment), or
Control is performed so that the antennas 1 and 2 are not connected to the first and second receiving systems (second embodiment). (Step 102).

Next, the synchronization control circuit 9 outputs the synchronization word UW
Is detected (step 103), and if detected, the transmission / reception timing of the own station is determined based on the detection timing, and the operation shifts to the TDD operation (step 10).
4). Next, the synchronization control circuit 9 outputs the mode switching signal V
_{CONT is set} to the high level, and thereafter, the reception mode is set to the normal reception mode (step 105). On the other hand, step 103
If the synchronization word UW cannot be detected in step, it is checked whether the set time T1 has elapsed since the base station started up (step 106).
The subsequent processing is continued. If the synchronization word UW cannot be detected even after the set time T1 has elapsed, the synchronization control circuit 9 sets the mode switching signal V _CONT to high level to set the reception mode to the normal reception mode (step 107).

Thereafter, in a state where the received signal is not attenuated, the synchronization control circuit 9 checks whether the synchronization word UW has been detected (step 108), and if it can detect the transmission word, determines the transmission / reception timing of its own station based on the detection timing. (Step 109). Step 108
If the synchronization word UW cannot be detected in step, it is checked whether or not the set time T2 has elapsed after shifting to the normal reception mode (step 110).
The subsequent processing is continued. If the synchronization word UW cannot be detected even after the set time T2 has elapsed, the operation shifts to the TDD operation at the own station timing (step 111).

(C) Third Embodiment In the third embodiment, when an input larger than a predetermined value is detected in a reception slot in the normal reception mode, it is determined that synchronization with another station at the same location or a neighboring station is not established. To the synchronous control receiving mode to perform synchronous control. FIG.
0 is a configuration diagram of the base station transmitting / receiving apparatus of the third embodiment, and the same parts as those of the first embodiment of FIG. 3 are denoted by the same reference numerals.
The difference from the first embodiment is that (1) limiter amplifiers 17 and 2
Received signal strength RSSI1, RSSI of antennas 1, 2 detected by 7
2 is input to the synchronization control circuit 9;
Is to automatically shift from normal reception mode to synchronous control reception mode when an input larger than a certain value is detected,
(3) The synchronization control circuit 9 automatically returns from the synchronous control reception mode to the normal reception mode after the completion of the synchronization control.

FIG. 21 is a block diagram of the synchronization control circuit 9 according to the third embodiment. Reference numeral 9a denotes a controller which controls the detection of the synchronization word UW from the demodulated data and the synchronization word U.
Control for synchronizing the transmission / reception timing of the own station with the transmission / reception timing of another station by generating a timing signal based on the detection of W, and generating a reset signal B upon completion of the synchronization control to return from the synchronous control reception mode to the normal reception mode And the like. 9b is a reference voltage generator for generating a reference voltage Vr, and 9c and 9d are reference voltages and received signal strengths RSSI1 and RSI output from limiter amplifiers 17 and 27.
This is a comparator that compares SI2 with the received signal strength RSSI1, RSS
When I2 is higher than the reference voltage Vr, a high-level signal is output. 9e is an OR gate, and the received signal strength RSSI1,
When one of the RSSI2 becomes higher than the reference voltage Vr, that is, when a strong signal is detected in the reception slot, it is determined that the transmission / reception timing of the other station and the own station is not synchronized, and the high level signal A is output. I do. 9f is a flip-flop, which is (1) reset at the initial stage, outputs a high-level signal V _CONT to enter the normal reception mode, and (2) when one of the received signal strengths RSSI1 and RSSI2 exceeds the reference voltage ( When a high-level signal A is generated), a low-level mode switching signal V _CONT is output to switch to the synchronous control reception mode,
(3) When the synchronization control is completed, the reset is performed by the reset signal B output from the controller 9a, and the mode is returned to the normal reception mode.

FIG. 22 is an operation time chart of the synchronous control circuit of the third embodiment. In normal reception mode, (V
_{When one of} the received signal strengths RSSI1 and RSSI2 becomes equal to or higher than the reference voltage Vr and the signal A is generated, the flip-flop 9f is set and the synchronous control reception mode ( _VCONT = low level) is set. In the synchronous control reception mode, the attenuators 11, 21 (FIG. 20) enter the attenuation operation state. As a result, a strong input signal from another station is attenuated and input to the demodulation unit 5, which demodulates the received data and inputs it to the controller 9a of the synchronization control circuit 9. The controller 9a controls the detection of the synchronization word UW, and upon detecting the synchronization word UW, outputs a transmission / reception timing signal based on the detection timing to synchronize the transmission / reception timing of the own station and the other station. Further, the controller 9a generates a reset signal B, resets the flip-flop 9f, and returns to the normal reception mode (V _CONT = high level).

In the above, the synchronization control circuit 9 of the first embodiment is described.
The third embodiment is configured by inputting the received signal strengths RSSI1 and RSSI2 to the synchronous control circuit 9 of the second embodiment (see FIG. 15).
The third embodiment can be configured by inputting the received signal strengths RSSI1 and RSSI2 to the third embodiment. As described above, the present invention has been described with reference to the embodiments. However, the present invention can be variously modified in accordance with the gist of the present invention described in the claims, and the present invention does not exclude these.

[0040]

As described above, according to the present invention, synchronization of transmission / reception timing between base stations can be established using the air synchronization method, and a strong input signal from another station is attenuated and received. Without causing deterioration or breakage of the
Further, the receiving sensitivity is not reduced. Further, according to the present invention, since the transmission / reception timing of the own station can be synchronized with the transmission / reception timing of another station, the restriction on the installation location of the base station can be eliminated, thereby enabling the effective installation of the base station. Become. Further, according to the invention, when a strong transmission wave from a base station already operating at the same location or adjacent is received, the own station can be started up while synchronizing transmission and reception between the own station and another station. As a result, it becomes easy for a plurality of PHS providers to increase the number of base stations in the same area, or to install a plurality of base station apparatuses in one installation place such as WLL to accommodate many subscribers.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a first principle of the present invention.

FIG. 2 is a diagram illustrating a second principle of the present invention.

FIG. 3 is a configuration diagram of a base station transmitting / receiving apparatus according to a first embodiment.

FIG. 4 is a circuit configuration of an attenuator.

FIG. 5 is a diagram illustrating the relationship between the control voltage Vc of the attenuator and the amount of attenuation.

FIG. 6 is another circuit configuration of the attenuator.

FIG. 7 is an operation explanatory diagram of FIG. 6;

FIG. 8 is a configuration diagram of an antenna switch.

FIG. 9 is a circuit configuration of a switch.

FIG. 10 is an operation explanatory diagram of each unit of the transmission / reception unit during normal control.

FIG. 11 is an explanatory diagram of a signal format and timing detection.

FIG. 12 is an operation explanatory diagram of each section of the transmission / reception device in the synchronization control of the first embodiment.

FIG. 13 is a configuration diagram of an attenuator control signal generator.

FIG. 14 is a table illustrating the relationship between modes and various signals.

FIG. 15 is a configuration diagram of a base station transmitting / receiving apparatus according to a second embodiment.

FIG. 16 is an operation explanatory diagram of each section of the transmission / reception device in the synchronization control of the second embodiment.

FIG. 17 is an explanatory diagram of switch output terminals and switch control signals in each mode.

FIG. 18 is a _table illustrating the relationship between signals TRS and V _CONT and switch control signals in each mode.

FIG. 19 is a flowchart of a synchronization control process.

FIG. 20 is a configuration diagram of a base station transmitting / receiving apparatus according to a third embodiment.

FIG. 21 is a configuration diagram of a synchronization control circuit in a third embodiment.

FIG. 22 is an operation time chart of the synchronization control circuit.

FIG. 23 is an explanatory diagram of transmission / reception timing of the 4-channel multiplex TDMA-TDD system.

[Explanation of symbols]

 TPA: Transmission power amplifier FE: Front end DM: Demodulation unit ANT: Antenna ANT-SW: Antenna switch AT: Attenuation means TRMG: Signal generation unit SYCC: Synchronization control unit

Continued on the front page (51) Int.Cl. ⁶ Identification code FI H04Q 7/26 7/30

Claims (10)

[Claims] 1. A base station transmitting and receiving apparatus that repeats a transmission mode and a reception mode, transmits a signal in the transmission mode, and receives a signal in the reception mode. A transmission power amplifier that is turned off at the front end, a front end that amplifies the antenna reception signal and performs frequency conversion, a demodulation unit that is provided behind the front end and that demodulates data from the reception signal, that is provided between the front end and the antenna, and that transmits and receives signals from its own station. An attenuating means for attenuating a received signal in a synchronous reception mode for synchronizing timing with transmission / reception timing of another base station. 2. The transmission / reception apparatus of a base station according to claim 1, wherein said attenuation means is a switch, and is turned off in a synchronous reception mode. 3. The transmission / reception apparatus of a base station according to claim 1, wherein the transmission / reception apparatus further comprises: a signal generation unit for generating a signal indicating whether the mode is a transmission mode or a reception mode; A synchronous control unit for controlling switching between the mode and the mode. 4. The transmission / reception apparatus of a base station according to claim 3, wherein the synchronization control section detects a reception signal strength, and compares the reception signal strength with a set value in a normal reception mode. Means for switching from the normal reception mode to the synchronous reception mode when the received signal strength exceeds the set value.In the synchronous reception mode, the transmission / reception timing of the other station is identified from the demodulated data and the transmission / reception of the own station and the other station is performed. Means for switching from a synchronous reception mode to a normal reception mode when timing synchronization is established. 5. The transmission / reception apparatus of a base station according to claim 4, wherein the synchronization control unit detects a synchronization word from a signal transmitted by another base station transmission / reception apparatus in a transmission mode, and performs timing of transmission / reception of the other station. Is characterized. 6. A base station transmitting / receiving apparatus that repeats a transmission mode and a reception mode, transmits a signal in the transmission mode, and receives a signal in the reception mode, wherein the transmission power amplifier turns on in the transmission mode and turns off in the reception mode. A front end for signal amplification and frequency conversion; an antenna switch for connecting an antenna to the transmission side in a synchronous reception mode for synchronizing the transmission / reception timing of the own station with the transmission / reception timing of another base station; A transmission / reception apparatus for a base station, comprising: a demodulation unit that demodulates data; a unit that is provided between a front end and an antenna switch, attenuates an input signal in a transmission mode and passes a reception signal in a reception mode. 7. The transmission / reception apparatus for a base station according to claim 6, wherein the attenuating means is a switch, which is turned off in a transmission mode and turned on in a reception mode. 8. The transmission / reception apparatus of a base station according to claim 6, wherein the transmission / reception apparatus further includes a signal generation unit for generating a signal indicating whether the transmission mode is the reception mode or the reception mode. A synchronous control unit for controlling switching between the mode and the mode. 9. The transmission / reception apparatus of a base station according to claim 8, wherein the synchronization control section detects a reception signal strength, and compares the reception signal strength with a set value in a normal reception mode. Means for switching from the normal reception mode to the synchronous reception mode when the received signal strength exceeds the set value.In the synchronous reception mode, the transmission / reception timing of the other station is identified from the demodulated data and the transmission / reception of the own station and the other station is performed. Means for switching from a synchronous reception mode to a normal reception mode when timing synchronization is established. 10. The transmission / reception apparatus of a base station according to claim 9, wherein the synchronization control unit detects a synchronization word from a signal transmitted by another base station transmission / reception apparatus in a transmission mode, and performs transmission / reception timing of the other station. Is characterized.